Actions of the pyrethroid insecticides cismethrin and cypermethrin on house fly Vssc1 sodium channels expressed in Xenopus oocytes

Voltage-sensitive sodium channels encoded by the Vssc1 gene of the house fly (Musca domestica) were expressed in Xenopus laevis oocytes in combination with the tipE gene product of Drosophila melanogaster and were characterized by two-electrode voltage clamp. Vssc1/tipE sodium channels expressed in oocytes were highly sensitive to tetrodotoxin; half-maximal inhibition of sodium currents by tetrodotoxin was obtained at a concentration of 2.4 nM. Cismethrin, a pyrethroid that produces Type I effects on intact nerve, slowed the inactivation of sodium currents carried by Vssc1/tipE channels during a depolarizing pulse and induced a tail current after repolarization that decayed with a first-order time constant of approximately 650 ms. The voltage dependence of activation and steady-state inactivation of cismethrin-modified channels were shifted to more negative potentials. Cypermethrin, a pyrethroid with Type II effects on intact nerve, also prolonged the inactivation of Vssc1/tipE sodium channels and induced a tail current. However, the cypermethrin-induced tail current was extremely persistent, decaying with a first-order time constant of approximately 42 s. Unlike cismethrin, the effect of cypermethrin was use dependent, requiring repeated depolarizing pulses for the full development of modified sodium currents. The divergent effects of cismethrin and cypermethrin on Vssc1/tipE sodium channels expressed in oocytes are consistent with the actions of these and related compounds on sodium channels in invertebrate and vertebrate nerve preparations and provide insight into the mechanisms underlying the production of Type I and II effects on neuronal excitability. Arch. Insect Biochem. Physiol. 38:126–136, 1998. © 1998 Wiley-Liss, Inc.     

Three mutations identified in the voltage-sensitive sodium channel alpha-subunit gene of permethrin-resistant human head lice reduce the permethrin sensitivity of house fly Vssc1 sodium channels expressed in Xenopus oocytes

Point mutations in the para-orthologous sodium channel alpha-subunit of the head louse (M815I, T917I, and L920F) are associated with permethrin resistance and DDT resistance. These mutations were inserted in all combinations using site-directed mutagenesis at the corresponding amino acid sequence positions (M827I, T929I, and L932F) of the house fly para-orthologous voltage-sensitive sodium channel alpha-subunit (Vssc1(WT)) gene and heterologously co-expressed with the sodium channel auxiliary subunit of house fly (Vsscbeta) in Xenopus oocytes. The double mutant possessing M827I and T929I (Vssc1(MITI)/Vsscbeta) caused a approximately 4.0mV hyperpolarizing shift and the triple mutant, Vssc1(MITILF)/Vsscbeta, caused a approximately 3.2mV depolarizing shift in the voltage dependence of activation curves. Vssc1(MITI)/Vsscbeta, Vssc1(TILF)/Vsscbeta, and Vssc1(MITILF)/Vsscbeta caused depolarizing shifts ( approximately 6.6, approximately 7.6, and approximately 8.8mV, respectively) in the voltage dependence of steady-state inactivation curves. The M827I and L932F mutations reduced permethrin sensitivity when expressed alone but the T929I mutation, either alone or in combination, virtually abolished permethrin sensitivity. Thus, the T929I mutation is the principal cause of permethrin resistance in head lice. Comparison of the expression rates of channels containing single, double and triple mutations with that of Vssc1(WT)/Vsscbeta channels indicates that the M827I mutation may play a role in rescuing the decreased expression of channels containing T929I.     

The V410M mutation associated with pyrethroid resistance in Heliothis virescens reduces the pyrethroid sensitivity of house fly sodium channels expressed in Xenopus oocytes

Some strains of Heliothis virescens carry a novel sodium channel mutation, corresponding to the replacement of Val410 by Met (designated V410M) in the house fly Vssc1 sodium channel, that is genetically and physiologically associated with pyrethroid resistance. To test the functional significance of this mutation, we created a house fly Vssc1 sodium channel containing the V410M mutation by site-directed mutagenesis, expressed wildtype and specifically mutated sodium channels in Xenopus laevis oocytes, and evaluated the effects of the V410M mutation on the functional and pharmacological properties of the expressed channels by two-electrode voltage clamp. The V410M mutation caused depolarizing shifts of approximately 9mV and approximately 5mV in the voltage dependence of activation and steady-state inactivation, respectively, of Vssc1 sodium channels. The V410M mutation also reduced the sensitivity of Vssc1 sodium channels to the pyrethroid cismethrin at least 10-fold and accelerated the decay of cismethrin-induced sodium tail currents. The degree of resistance conferred by the V410M mutation in the present study is sufficient to account for the degree of pyrethroid resistance in H. virescens that is associated with this mutation. Although Val410 is located in a sodium channel segment identified as part of the binding site for batrachotoxin, the V410M mutation did not alter the sensitivity of house fly sodium channels to batrachotoxin. The effects of the V410M mutation on the voltage dependence and cismethrin sensitivity of Vssc1 sodium channels were indistinguishable from those caused by another sodium channel point mutation, replacement of Leu1014 by Phe (L1014F), that is the cause of knockdown resistance to pyrethroids in the house fly. The positions of the V410M and L1014F mutations in models of the tertiary structure of sodium channels suggest that the pyrethroid binding site on the sodium channel alpha subunit is located at the interface between sodium channel domains I and II.     

Mutations in the house fly Vssc1 sodium channel gene associated with super-kdr resistance abolish the pyrethroid sensitivity of Vssc1/tipE sodium channels expressed in Xenopus oocytes

The super-kdr insecticide resistance trait of the house fly confers resistance to pyrethroids and DDT by reducing the sensitivity of the fly nervous system. The super-kdr genetic locus is tightly linked to the Vssc1 gene, which encodes a voltage-sensitive sodium channel alpha subunit that is the principal site of pyrethroid action. DNA sequence analysis of Vssc1 alleles from several independent super-kdr fly strains identified two amino acid substitutions associated with the super-kdr trait: replacement of leucine at position 1014 with phenylalanine (L1014F), which has been shown to cause the kdr resistance trait in this species, and replacement of methionine at position 918 with threonine (M918T). We examined the functional significance of these mutations by expressing house fly sodium channels containing them in Xenopus laevis oocytes and by characterizing the biophysical properties and pyrethroid sensitivities of the expressed channels using two-electrode voltage clamp. House fly sodium channels that were specifically modified by site-directed mutagenesis to contain the M918T/L1014F double mutation gave reduced levels of sodium current expression in oocytes but otherwise exhibited functional properties similar to those of wildtype channels and channels containing the L1014F substitution. However, M918T/L1014F channels were completely insensitive to high concentrations of the pyrethroids cismethrin and cypermethrin. House fly sodium channels specifically modified to contain the M918T single mutation, which is not known to exist in nature except in association with the L1014F mutation, gave very small sodium currents in oocytes. Assays of these currents in the presence of high concentrations of cismethrin suggest that this mutation alone is sufficient to abolish the pyrethroid sensitivity of house fly sodium channels. These results define the functional significance of the Vssc1 mutations associated with the super-kdr trait of the house fly and are consistent with the hypothesis that the super-kdr trait arose by selection of a second-site mutation (M918T) that confers to flies possessing it even greater resistance than the kdr allele containing the L1014F mutation.     

Four novel sequences in Drosophila melanogaster homologous to the auxiliary Para sodium channel subunit TipE

TipE is an auxiliary subunit of the Drosophila Para sodium channel. Here we describe four sequences, TEH1-4, homologous to TipE in the Drosophila melanogaster genome, harboring all typical structures of both TipE and the beta-Subunit family of big-conductance Ca(2+)-activated potassium channels: short cytosolic N- and C-terminal stretches, two transmembrane domains, and a large extracellular loop with two disulfide bonds. Whereas TEH1 and TEH2 lack the TipE-specific extension in the extracellular loop, both TEH3 and TEH4 possess two extracellular EGF-like domains. A CNS-specific expression was found for TEH1, while TEH2-4 were more widely expressed. The genes for TEH2-4 are localized close to the tipE gene on chromosome 3L. Coexpression of TEH subunits with Para in Xenopus oocytes showed a strong (30-fold, TEH1), medium (5- to 10-fold, TEH2 and TEH3), or no (TEH4) increase in sodium current amplitude, while TipE increased the current 20-fold. In addition, steady-state inactivation and the recovery from fast inactivation were altered by coexpression of Para with TEH1. We conclude that members of the TEH-family are auxiliary subunits for Para sodium channels and possibly other ion channels.     

The extracellular domain of the beta1 subunit is both necessary and sufficient for beta1-like modulation of sodium channel gating.

The type IIA voltage-gated sodium Na(+) channel from rat brain is composed of a large, pore-forming alpha subunit and the auxiliary subunits beta1 and beta2. When expressed in Xenopus oocytes, the beta1 subunit modulates the gating properties of the type IIA alpha subunit, resulting in acceleration of both inactivation and recovery from inactivation and in a negative shift in the voltage dependence of fast inactivation. The beta1 subunit is composed of an extracellular domain with a single immunoglobulin-like fold, a single transmembrane segment, and a small intracellular domain. A series of chimeras with exchanges of domains between the Na(+) channel beta1 and beta2 subunits and between beta1 and the structurally related protein myelin P0 were constructed and analyzed by two-microelectrode voltage clamp in Xenopus oocytes. Only chimeras containing the beta1 extracellular domain were capable of beta1-like modulation of Na(+) channel gating. Neither the transmembrane segment nor the intracellular domain was required for modulation, although mutation of Glu(158) within the transmembrane domain altered the voltage dependence of steady-state inactivation. A truncated beta1 subunit was engineered in which the beta1 extracellular domain was fused to a recognition sequence for attachment of a glycosylphosphatidylinositol membrane anchor. The beta1(ec)-glycosylphosphatidylinositol protein fully reproduced modulation of Na(+) channel inactivation and recovery from inactivation by wild-type beta1. Our findings demonstrate that extracellular domain of the beta1 subunit is both necessary and sufficient for the modulation of Na(+) channel gating.     

Individual variation and hormonal modulation of a sodium channel beta subunit in the electric organ correlate with variation in a social signal

The sodium channel beta1 subunit affects sodium channel gating and surface density, but little is known about the factors that regulate beta1 expression or its participation in the fine control of cellular excitability. In this study we examined whether graded expression of the beta1 subunit contributes to the gradient in sodium current inactivation, which is tightly controlled and directly related to a social behavior, the electric organ discharge (EOD), in a weakly electric fish Sternopygus macrurus. We found the mRNA and protein levels of beta1 in the electric organ both correlate with EOD frequency. We identified a novel mRNA splice form of this gene and found the splicing preference for this novel splice form also correlates with EOD frequency. Androgen implants lowered EOD frequency and decreased the beta1 mRNA level but did not affect splicing. Coexpression of each splice form in Xenopus oocytes with either the human muscle sodium channel gene, hNav1.4, or a Sternopygus ortholog, smNav1.4b, sped the rate of inactivation of the sodium current and shifted the steady-state inactivation toward less negative membrane potentials. The translational product of the novel mRNA splice form lacks a previously identified important tyrosine residue but still functions normally. The properties of the fish alpha and coexpressed beta1 subunits in the oocyte replicate those of the electric organ's endogenous sodium current. These data highlight the role of ion channel beta subunits in regulating cellular excitability.     

PCR-generated conspecific sodium channel gene probe for the house fly.

A segment of the house fly (Musca domestica) homologue of the para (paralytic) sodium channel gene of Drosophila melanogaster was isolated by using mixed sequence oligonucleotide primers in the polymerase chain reaction (PCR). The specificity of the procedure was demonstrated by genomic Southern analysis using the housefly PCR amplification product as a probe and by DNA sequence analysis. The latter showed structural homology to the para gene, but not to the corresponding region of DSC1, another D. melanogaster gene with structural similarity to vertebrate sodium channel genes.     

Regulation of Ca-sensitive inactivation of a 1-type Ca2+ channel by specific domains of beta subunits.

Ca2+ channel auxiliary beta subunits have been shown to modulate voltage-dependent inactivation of various types of Ca2+ channels. The beta1 and beta2 subunits, that are differentially expressed with the L-type alpha1 Ca2+ channel subunit in heart, muscle and brain, can specifically modulate the Ca2+-dependent inactivation kinetics. Their expression in Xenopus oocytes with the alpha1C subunit leads, in both cases, to biphasic Ca2+ current decays, the second phase being markedly slowed by expression of the beta2 subunit. Using a series of beta subunit deletion mutants and chimeric constructs of beta1 and beta2 subunits, we show that the inhibitory site located on the amino-terminal region of the beta2a subunit is the major element of this regulation. These results thus suggest that different splice variants of the beta2 subunit can modulate, in a specific way, the Ca2+ entry through L-type Ca2+ channels in different brain or heart regions.     

The intracellular segment of the sodium channel beta 1 subunit is required for its efficient association with the channel alpha subunit

Sodium channels consist of a pore-forming alpha subunit and auxiliary beta 1 and beta 2 subunits. The subunit beta 1 alters the kinetics and voltage-dependence of sodium channels expressed in Xenopus oocytes or mammalian cells. Functional modulation in oocytes depends on specific regions in the N-terminal extracellular domain of beta 1, but does not require the intracellular C-terminal domain. Functional modulation is qualitatively different in mammalian cells, and thus could involve different molecular mechanisms. As a first step toward testing this hypothesis, we examined modulation of brain Na(V)1.2a sodium channel alpha subunits expressed in Chinese hamster lung cells by a mutant beta1 construct with 34 amino acids deleted from the C-terminus. This deletion mutation did not modulate sodium channel function in this cell system. Co-immunoprecipitation data suggest that this loss of functional modulation was caused by inefficient association of the mutant beta 1 with alpha, despite high levels of expression of the mutant protein. In Xenopus oocytes, injection of approximately 10,000 times more mutant beta 1 RNA was required to achieve the level of functional modulation observed with injection of full-length beta 1. Together, these findings suggest that the C-terminal cytoplasmic domain of beta 1 is an important determinant of beta1 binding to the sodium channel alpha subunit in both mammalian cells and Xenopus oocytes.     

OD1, the first toxin isolated from the venom of the scorpion Odonthobuthus doriae active on voltage-gated Na+ channels

In this study, we isolated and pharmacologically characterized the first alpha-like toxin from the venom of the scarcely studied Iranian scorpion Odonthobuthus doriae. The toxin was termed OD1 and its primary sequence was determined: GVRDAYIADDKNCVYTCASNGYCNTECTKNGAESGYCQWIGRYGNACWCIKLPDEVPIRIPGKCR. Using the two-electrode voltage clamp technique, the pharmacological effects of OD1 were studied on three cloned voltage-gated Na+ channels expressed in Xenopus laevis oocytes (Na(v)1.2/beta1, Na(v)1.5/beta1, para/tipE). The inactivation process of the insect channel, para/tipE, was severely hampered by 200 nM of OD1 (EC50 = 80+/-14 nM) while Na(v)1.2/beta1 still was not affected at concentrations up to 5 microM. Na(v)1.5/beta1 was influenced at micromolar concentrations.     

Differential Effects of TipE and a TipE-Homologous Protein on Modulation of Gating Properties of Sodium Channels from Drosophila melanogaster

β subunits of mammalian sodium channels play important roles in modulating the expression and gating of mammalian sodium channels. However, there are no orthologs of β subunits in insects. Instead, an unrelated protein, TipE in Drosophila melanogaster and its orthologs in other insects, is thought to be a sodium channel auxiliary subunit. In addition, there are four TipE-homologous genes (TEH1-4) in D. melanogaster and three to four orthologs in other insect species. TipE and TEH1-3 have been shown to enhance the peak current of various insect sodium channels expressed in Xenopus oocytes. However, limited information is available on how these proteins modulate the gating of sodium channels, particularly sodium channel variants generated by alternative splicing and RNA editing. In this study, we compared the effects of TEH1 and TipE on the function of three Drosophila sodium channel splice variants, DmNa_v9-1, DmNa_v22, and DmNa_v26, in Xenopus oocytes. Both TipE and TEH1 enhanced the amplitude of sodium current and accelerated current decay of all three sodium channels tested. Strikingly, TEH1 caused hyperpolarizing shifts in the voltage-dependence of activation, fast inactivation and slow inactivation of all three variants. In contrast, TipE did not alter these gating properties except for a hyperpolarizing shift in the voltage-dependence of fast inactivation of DmNa_v26. Further analysis of the gating kinetics of DmNa_v9-1 revealed that TEH1 accelerated the entry of sodium channels into the fast inactivated state and slowed the recovery from both fast- and slow-inactivated states, thereby, enhancing both fast and slow inactivation. These results highlight the differential effects of TipE and TEH1 on the gating of insect sodium channels and suggest that TEH1 may play a broader role than TipE in regulating sodium channel function and neuronal excitability in vivo.     

Independent and joint modulation of rat Nav1.6 voltage-gated sodium channels by coexpression with the auxiliary β1 and β2 subunits

The Na_v1.6 voltage-gated sodium channel α subunit isoform is the most abundant isoform in the brain and is implicated in the transmission of high frequency action potentials. Purification and immunocytochemical studies imply that Na_v1.6 exist predominantly as Na_v1.6 + β1 + β2 heterotrimeric complexes. We assessed the independent and joint effects of the rat β1 and β2 subunits on the gating and kinetic properties of rat Na_v1.6 channels by recording whole-cell currents in the two-electrode voltage clamp configuration following transient expression in Xenopus oocytes. The β1 subunit accelerated fast inactivation of sodium currents but had no effect on the voltage dependence of their activation and steady-state inactivation and also prevented the decline of currents following trains of high-frequency depolarizing prepulses. The β2 subunit selectively retarded the fast phase of fast inactivation and shifted the voltage dependence of activation towards depolarization without affecting other gating properties and had no effect on the decline of currents following repeated depolarization. The β1 and β2 subunits expressed together accelerated both kinetic phases of fast inactivation, shifted the voltage dependence of activation towards hyperpolarization, and gave currents with a persistent component typical of those recorded from neurons expressing Na_v1.6 sodium channels. These results identify unique effects of the β1 and β2 subunits and demonstrate that joint modulation by both auxiliary subunits gives channel properties that are not predicted by the effects of individual subunits.     

Single-channel analysis of inactivation-defective rat skeletal muscle sodium channels containing the F1304Q mutation.

The intracellular linker between domains III and IV of the voltage-gated Na channel mediates fast inactivation. Targeted alteration of one or more of a triplet of hydrophobic amino acids within this linker region results in a marked slowing in the decay of ionic current. The mechanism of this defective inactivation was explored in rat skeletal muscle sodium channels (mu 1) containing the F1304Q mutation in Xenopus laevis oocytes with and without coexpression of the rat brain beta 1 subunit. Cell-attached single-channel patch-clamp recordings revealed that the mu 1-F1304Q channel reopens multiple times with open times that are prolonged compared with those of the wild-type channel. Coexpression of the beta 1 subunit stabilized a dominant nonbursting gating mode and accelerated the activation kinetics of mu 1-F1304Q but did not modify mean open time or fast-inactivation kinetics. A Markov gating model incorporating separate fast- and slow-inactivation particles reproduced the results by assuming that the F1304Q mutation specifically influences transitions to and from fast-inactivated states. These effects are independent of interactions of the mutant channel with the beta 1 subunit and do not result from a change in modal gating behavior. These results indicate that F1304Q mutant channels can still enter the inactivated state but do so reversibly and with altered kinetics.     

禾谷缢管蚜钠通道辅助亚基对钠通道基因表达水平及杀虫剂敏感性的影响

【目的】通过分析禾谷缢管蚜Rhopalosiphum padi钠通道辅助亚基对钠通道功能的影响,探究辅助亚基在钠离子通道的门控性质中的作用。【方法】分别显微注射dsRpNa_vH1和dsRpNa_vH2对钠通道基因RpNa_vH1和RpNa_vH2进行RNAi后,采用实时定量PCR(qRT-PCR)技术测定禾谷缢管蚜成蚜5个钠通道辅助亚基基因(RpTEH1, RpTEH2, RpTEH3, RpTEH4和RpTipE)的表达量;利用qRT-PCR技术和杀虫剂生物测定分别测定RNAi干扰RpTipE对禾谷缢管蚜成蚜钠通道及其辅助亚基基因表达量以及LC₅₀浓度高效氯氟氰菊酯敏感性的影响;利用双电压钳技术检测非洲爪蟾Xenopus laevis卵母细胞单独注射果蝇Drosophila钠通道基因DmNa_v22 cRNA及DmNa_v22 cRNA分别与果蝇钠通道辅助亚基基因DmTipE及禾谷缢管蚜钠通道辅助亚基基因RpTEH2, RpTEH3, RpTEH4和RpTipE的cRNA共注射时的Na⁺电流,分析禾谷缢管蚜钠通道辅助亚基的功能。【结果】RNAi敲降禾谷缢管蚜成虫钠通道基因RpNa_vH1后,禾谷缢管蚜成蚜4个钠通道辅助亚基基因RpTEH1, RpTEH2, RpTEH3以及RpTipE的表达量显著降低,RpTEH4的表达量没有显著变化;RNAi敲降禾谷缢管蚜钠通道基因RpNa_vH2后,钠通道辅助亚基基因RpTEH1, RpTEH2, RpTEH3, RpTEH4和RpTipE的表达量都显著降低。RNAi敲降禾谷缢管蚜钠通道辅助亚基基因RpTipE后,钠通道基因RpNa_vH1和RpNa_vH2及钠通道辅助亚基基因RpTEH1, RpTEH2, RpTEH3和RpTEH4的表达量都显著降低。RNAi干扰RpTipE后48 h时,禾谷缢管蚜成蚜对LC₅₀浓度的高效氯氰菊酯的敏感性降低。双电压钳技术检测结果表明,将果蝇钠通道基因DmNa_v22 cRNA分别与禾谷缢管蚜钠通道辅助亚基基因RpTEH2, RpTEH3, RpTEH4和RpTipE cRNA共注射到非洲爪蟾卵母细胞中时均提高果蝇钠通道DmNa_v22的Na⁺电流。【结论】禾谷缢管蚜钠通道辅助亚基可能参与调节该虫钠离子通道的门控性质。     

Calcium channel function regulated by the SH3-GK module in beta subunits

beta subunits of voltage-gated calcium channels (VGCCs) regulate channel trafficking and function, thereby shaping the intensity and duration of intracellular changes in calcium. beta subunits share limited sequence homology with the Src homology 3-guanylate kinase (SH3-GK) module of membrane-associated guanylate kinases (MAGUKs). Here, we show biochemical similarities between beta subunits and MAGUKs, revealing important aspects of beta subunit structure and function. Similar to MAGUKs, an SH3-GK interaction within beta subunits can occur both intramolecularly and intermolecularly. Mutations that disrupt the SH3-GK interaction in beta subunits alter channel inactivation and can inhibit binding between the alpha(1) and beta subunits. Coexpression of beta subunits with complementary mutations in their SH3 and GK domains rescues these deficits through intermolecular beta subunit assembly. In MAGUKs, the SH3-GK module controls protein scaffolding. In beta subunits, this module regulates the inactivation of VGCCs and provides an additional mechanism for tuning calcium responsiveness.     

Characterization of the nicotinic acetylcholine receptor subunit gene Mdalpha2 from the house fly, Musca domestica

A nicotinic acetylcholine receptor (nAChR) subunit gene, Mdalpha2, was isolated and characterized from the house fly, Musca domestica. This is the first nAChR family member cloned from house flies. Mdalpha2 had a cDNA of 2,607 bp, which included a 696 bp 5'-untranslated region (UTR), an open reading frame of 1,692 bp, and a 219 bp 3'-UTR. Its deduced amino acid sequence possesses the typical characteristics of nAChRs. Mdalpha2 genomic sequence was 11.2 kb in length in the aabys strain and 10.9 kb in the OCR strain, including eight exons and seven introns. Based on the deduced amino acid sequence, Mdalpha2 had the closest phylogenetic relationship to the Drosophila melanogaster Dalpha2 and Anopheles gambiae Agamalpha2, and a similar genomic structure to Dalpha2. Quantitative real-time PCR analysis showed that Mdalpha2 is expressed in the head and the thorax at 150- and 8.5-fold higher levels than in the abdomen. Linkage analysis of a Mdalpha2 polymorphism indicates this gene is on autosome 2. The importance of these results in understanding the diversity and phylogenetic relationships of insect nAChRs, the physiology of nAChRs in the house fly, and the utility of nAChR sequences in resistance detection/monitoring is discussed.